RU124423U1 - OPTICAL RADIO ELECTRONIC SEAL - Google Patents

Abstract

1. The optical electronic seal contains a housing 16, means for storing the sealing information (memory) 5 and data exchange with a portable and / or stationary reader 13, characterized in that it includes: eight digital sources of modulated optical radiation 1, eight digital optical radiation receivers 2, which are sequentially closed (optical emitter 1 with optical receiver 2) with optical cables 17, each of which contains a label in its shell frequency identification of the frequency range 125 kHz and a unique number is applied to each optical cable, providing control of the continuity of the light flux, violation of which indicates a violation of the integrity of the seal; an electric power source 3 providing electric elements of the seal; the microprocessor 4, which controls the electronic seal, encrypts the data transmitted over the radio channels 10, 14 and 15; a digital three-axis acceleration sensor (digital accelerometer) 6 for recording the shock loads that the seal is subjected to; digital detachment sensor 7 for use in the algorithms of operation of the seal information about its installation on the surface of the protected object and removal in order to activate the process of closing and sealing, as well as identification of the process of opening the seal or violation of its integrity; receiver of radio navigation signals of GLONASS / Beidou / GPS / GALILEO 8 systems with antenna unit 9 for determining the location of the seal, its speed of movement, generation of a time mark for the events of the seal; cellular mobile communication channel 10 for transmitting ciphers

Description

The utility model relates to the field of providing automated monitoring of the state of electronic sealing devices used as security devices against unauthorized entry, and can be used to seal vehicles, wagons, containers, garages, warehouses, etc. equipped with locking units.

An electronic sealing device is known, consisting of a body, a piece of rope permanently connected to it, a mechanism for its non-permanent fixation placed in the body cavity and interacting with the rope, the rope sensor and an electronic microcircuit connected to it, equipped with an information transfer element, are additionally located in the body cavity, with with the help of which an electromagnetic signal is generated, which is recorded by an external receiving device (utility model RU 51735, ЕВВ 39/02).

Known electronic seal RU 2358331, G09F 3/03, selected as a prototype, which includes a housing and a piece of cable, consisting of an outer shell surrounding at least one inner core, while one end of the cable is rigidly fixed in the housing and connected to the cable integrity control unit, the other working end of the cable, after installation on a lockable object, is fixed by a locking mechanism located in the housing, means for storing sealing information and exchanging data with a portable and / or stationary reader m Moreover, one inner core is made of an electrically conductive nonmetallic material with a high elongation, in the initial state it is stretched and forms an electrical circuit with another conductive core made, for example, of a copper conductor, and / or an outer sheath, while this circuit is electrically connected with a cable integrity control unit (three seals are presented).

The disadvantages of the devices of this group are the lack of remote monitoring of the integrity status of the seal (the reader must be brought to the devices of this group), the lack of operational data on the time and location of the seal at the time of violation of its integrity (or data on its location and time without breaking the integrity of the last session communication until it is destroyed by intruders in case of absenteeism at a given time for communication with a remote control station for the status of seals) in a remote control center for the condition of the seals b, the possibility of an attacker making a device that simulates the integrity of the electrical circuit of an electronic seal (for transmission to a data reader).

The technical objective of this solution is to provide the user at any time (regardless of the mutual remoteness of the control point and seal):

- information about the current integrity of the seal, its location and the time of the event (or its location and time without breaking the integrity of the last communication session before it was destroyed by the attackers when they failed to contact the remote control station for the status of the seals at a given time),

- the ability to save and read information about all occurring events with a seal,

- asymmetric encryption of the transmitted information to the control point and decryption of the received information from the control point,

- information about the speed of movement and acceleration of the seal,

- the ability to relay the received radio signals from the same optoelectronic seals to a remote control point,

- the ability to automatically register and transmit data on used disposable fiber optic cables (through radio frequency identification), due to which the integrity of the seal is controlled,

- the ability to automatically register and transfer data about a person who carries out legal installation or legal removal of seals through the use of radio frequency identification.

The problem is fundamentally solved by the fact that instead of a multilayer cable containing an electrically conductive material, an optical cable is inserted into the electronic seal prototype and instead of monitoring the integrity of the electrical circuit, the continuity of the modulated light flux is monitored in a certain way. In this connection, all components servicing the task of monitoring the integrity of the electric circuit were replaced by components providing control of the continuity of the light flux; and in addition, modules have been added that significantly expand the functionality of the electronic seal. In addition, the optical electronic seal (in contrast to the electrical prototype seal) does not use a locking mechanism. Those. In the electronic seal containing the housing, which includes the cable integrity control unit and the means for storing the sealing information, eight optical circuits are introduced instead of the cable, which are connected via optical cables (it is possible to control the integrity of one to eight circuits depending on how many optical cables are connected at the same time to the seal) through which the modulated light flux is transmitted from eight sources of optical radiation to eight optical For radiation receivers, each sheath of optical cables is connected with one RFID tag of the frequency range 125 kHz and a unique number is marked on each optical cable. In addition to storage means for sealing information, the seal enclosure includes: a microprocessor, a storage device, electric power sources, eight optical radiation sources, eight optical radiation detectors, a three-axis acceleration measurement sensor, a seal detachment sensor from the surface, an antenna unit and a radio navigation signal system receiver GLONASS / Beidou / GPS / GALILEO, mobile cellular communication channel, radio frequency identification communication channel in the frequency range 125 kHz, 136 kHz and 433 MHz, few communication channels range of 2.4 and 5 GHz. Means of storage of filling information are made combined with a storage device. The casing is made of radiolucent material, on the lower part of the casing there are elements of fastening the casing of the seal to the surface of the protected object. The seal is activated by the installation of electric power elements in its housing. A seal closes from one to eight loops by a serial connection of fiber optic disposable cables with RFID tags and is armed when the seal case is installed on the surface of the protected object. The power elements cannot be removed from the seal housing without tearing the seal housing off the surface. A seal is considered open or with a broken integrity when at least one optical cable is disconnected or an optical signal is transmitted via fiber optic cables from the optical radiation source to the optical radiation receivers (when the optical cable is destroyed), the seal body is torn off the surface (on which it is installed) or physical violation of the integrity of the shell of the seal. The seal turns off when the electric power elements are removed from its housing.

The technical result is achieved through the integrated use of modern computing tools and modern electronic components.

Figure 1 shows the functional diagram of an optical electronic seal.

The optical electronic seal contains eight digital sources of modulated optical radiation 1, eight digital optical radiation receivers 2, which are sequentially closed (optical emitter 1 with optical receiver 2) by optical cables 17, each of which contains a 125 kHz radio frequency identification mark in its envelope and Each optical cable has a unique number. Each optical emitter and optical receiver is directly connected by an electric network to an electric power source 3, from which they receive electrical energy. The electric energy source provides electric power through the electric network, microprocessor 4, storage device (storage means for sealing information) 5, digital three-axis acceleration sensor (digital accelerometer) 6, digital separation sensor 7, radio navigation signal receiver of GLONASS / Beidou / GPS / GALILEO 8 systems, mobile cellular communication channel 10, radio frequency identification communication channel at a frequency of 125 kHz 11, radio frequency identification communication channel at a frequency of 136 kHz 12, radio frequency identification communication channel authentication at a frequency of 433 MHz (means of exchanging data with a portable and / or stationary reader) 13, a short-range communication channel at a frequency of 2.5 GHz 14, a short-range communication channel at a frequency of 5 GHz 15, a decryption chip for the received information 19 from a remote control point by radio channels 10, 14 and 15. An optical electronic seal is located inside the sealed housing 16 with mounts to hold the seal on the surface of the protected object. Optical cables 17 with an RFID tag are located outside the sealed enclosure 16. The microprocessor 4 is operatively connected by direct one-way communication with the digital optical emitters 1 in order to control them. Digital optical radiation receivers 2 are functionally unidirectionally coupled to microprocessor 4 for transmitting information received from optical emitters 1. Microprocessor 4 is connected by direct and feedback feedback to memory unit 5 for reading microprogram from it, data and writing received data to it in accordance with microprogram requirements . The microprocessor 4 is connected by direct and feedback with a digital accelerometer 6 with the aim of transmitting data to the accelerometer with an indication of its threshold and reading from it data on the measured acceleration values along the three coordinate axes of the seal body. The microprocessor 4 is connected by direct and feedback with a digital tear-off sensor 7 with the aim of transmitting to the tear-off sensor information about the threshold of the tear-off sensor (the limit value of the movement of the seal body relative to the initial installation point on the surface) and receives information from it about the separation of the seal body from the surface. Microprocessor 4 is connected by direct and feedback to the receiver of radio navigation signals of the GLONASS / Beidou / GPS / GALILEO 8 systems in order to control its operation mode and obtain from it a mark of universal coordinated time, coordinates in any coordinate system and speed of the seal moving in space. The receiver of radio navigation signals of the GLONASS / Beidou / GPS / GALILEO 8 systems is connected by a functional feedback with the antenna unit 9 for receiving electromagnetic signals from it. The microprocessor 4 is connected by direct and feedback to the data transmission channel of the mobile cellular communication 10 in order to receive the data arriving at the seal from the remote control point, the microprocessor 4 is connected to the decryption chip of the received information 19 refers to it for the decryption algorithm of the information received via the cellular mobile radio channel 10 and gets the algorithm; as well as data transmission, which microprocessor 4 encrypts with its own code and transmits to a remote control point via a radio channel of cellular mobile communication 10. Microprocessor 4 is connected by feedback to a communication channel of radio frequency identification in the frequency range 125 kHz and receives data on the used fiber optic cables with tags RF identification at a frequency of 125 kHz 18. The microprocessor 4 is connected by feedback to the communication channel of the radio frequency identification in the frequency range 136 kHz and receives a command to start and ok start receiving and transmitting data using the radio frequency identification channel at a frequency of 433 MHz 13. The microprocessor 4 is connected by direct and feedback to a short-range data transmission channel 14 at a frequency of 2.5 GHz in order to receive, transmit and relay data coming to the seal from the same optical electronic seals for a remote control point. All information that is received and transmitted by the seal using the radio channel 14 is decrypted using the decryption chip 19 and is encrypted using the microprocessor 4. Information that is relayed by the radio channel 14 does not go through the encryption and decryption process. The microprocessor 4 is connected by direct and feedback to the short-range data transmission channel 15 at a frequency of 5 GHz in order to receive and transmit data from / to the control point. All information that is received and transmitted by the seal using the radio channel 15 is decrypted using the decryption chip 19 and is encrypted using microprocessor 4.

Claims (3)

1. The optical electronic seal contains a housing 16, means for storing the sealing information (memory) 5 and data exchange with a portable and / or stationary reader 13, characterized in that it includes: eight digital sources of modulated optical radiation 1, eight digital optical radiation receivers 2, which are sequentially closed (optical emitter 1 with optical receiver 2) with optical cables 17, each of which contains a label in its shell frequency identification of the frequency range 125 kHz and a unique number is applied to each optical cable, providing control of the continuity of the light flux, violation of which indicates a violation of the integrity of the seal; an electric power source 3 providing electric elements of the seal; the microprocessor 4, which controls the electronic seal, encrypts the data transmitted over the radio channels 10, 14 and 15; a digital three-axis acceleration sensor (digital accelerometer) 6 for recording the shock loads that the seal is subjected to; digital detachment sensor 7 for use in the algorithms of operation of the seal information about its installation on the surface of the protected object and removal in order to activate the process of closing and sealing, as well as identification of the process of opening the seal or violation of its integrity; receiver of radio navigation signals of GLONASS / Beidou / GPS / GALILEO 8 systems with antenna unit 9 for determining the location of the seal, its speed of movement, generation of a time mark for the events of the seal; a mobile cellular communication channel 10 for transmitting encrypted data about the state of the seal to a remote control point and receiving encrypted data from the control point to change the operation mode of the seal; a radio frequency identification communication channel at a frequency of 125 kHz 11 for the automatic identification of optical cables that control the integrity of the seal, as well as the possible identification of the employee who removes and / or installs the seal; a radio frequency identification communication channel at a frequency of 136 kHz 12 to enable or disable a radio frequency identification communication channel at a frequency of 433 MHz (means for exchanging data with a portable and / or stationary reader) 13; a short-range communication channel at a frequency of 2.5 GHz 14 for use in places where there is no cellular communication, and there is a need for low power consumption to transmit information about the status of several seals to a control point by transmitting and relaying received signals from one seal to another until until the signal reaches the data transmission / reception channel of the control point, as well as for setting the operating modes of the seal at the control point before starting the seals in operation; a short-range communication channel at a frequency of 5 GHz 15, used to transmit data to a control point in enclosed spaces and to determine the location of a seal in enclosed spaces (warehouses, holds, etc.) by trilateration relative to transceivers in the frequency range of 5 GHz of a control point; decryption chip 19 for decrypting information received from the control point on the radio channels 10, 14 and 15. 2. The seal according to claim 1, characterized in that the means of storing the filling information (storage device) 5 carries out not only the storage of the sealing information, but also the firmware for controlling the operation of the seal with the data set, as well as information about its condition. 3. The seal according to claim 1, characterized in that the housing is sealed with fastening elements to the surface of the protected object.

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